Mixture for Liquid Crystal Medium and Liquid Crystal Display Using the Same

ABSTRACT

The present invention provides a mixture for liquid crystal medium and a liquid crystal display using the same. The mixture for liquid crystal medium comprises: at least one anisotropic liquid crystal material and a polymerizable monomer which will polymerize under UV irradiation. The weight percentage of the polymerizable monomer accounts for 0.1% to 1% of the total mixture for liquid crystal medium. In the mixture for liquid crystal medium and a liquid crystal display using the same according to the present invention, by using a polymerizable monomer which will polymerize under UV irradiation and the appropriate content ratio, the polymer bump with small size and good uniformity can be obtained within the mixture for liquid crystal medium after the polymerization, which avoids the bad liquid crystal alignment and the light spot occurred at the dark state of the liquid crystal panel, and then increases the response rapid of the liquid crystal panel to obtain high contrast ratio and stable mass production.

This application claims priority to Chinese Patent Application SerialNo. 201210360685.1, named as “mixture for liquid crystal medium andliquid crystal display using the same”, filed on Sep. 21, 2012, thespecification of which is incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to the field of liquid crystal displaytechnology, and in particular to a mixture for liquid crystal medium anda liquid crystal display using the same.

2. The Related Arts

The liquid crystal used for twisted nematic (TN) or super twistednematic (STN) liquid crystal display is positive-type liquid crystal.The long axis of the liquid crystal molecules is parallel to the surfaceof the substrate when the power is off. The alignment direction of theliquid crystal molecules on the surface of the substrate depends on therubbing direction of alignment layer, which material usually ispolyimide. The alignment directions of the surface of both substratesare perpendicular to each other. Hence, the molecules within the liquidcrystal layer maintain in continuous twisted alignment state from thesurface of one substrate to the surface of the other substrate. Afterthe voltage is applied, the long axis of the liquid crystal moleculeswill tend to be aligned along the direction of the electric field. Thedrawback of the TN/STN type liquid crystal display is that it has smallviewing angle, brightness difference and significant chromaticaberration under large viewing angle, which needs to be improved by thecompensation film and thereby increases the manufacturing cost of thedisplay.

Multi-domain vertical alignment (MVA) TFT-LCD using negative type liquidcrystal and vertically aligned film material has solved the restrictionsof the viewing angle of TN/STN display. When no voltage is applied, thelong axis of the liquid crystal molecules is perpendicular to thesurface of the substrate. When the voltage is applied, the liquidcrystal molecules will topple down and the long axis of the liquidcrystal molecules will tend to be aligned along the vertical directionof the electric field. In order to solve the problems of the viewingangle, a sub-pixel is divided into multiple regions, so that the liquidcrystal molecules can topple down in different direction, which makesthe views of the display seen in different directions tend to be thesame. There are several ways to allow the liquid crystal molecules inthe different regions to be oriented in different directions in onesub-pixel. The first one is to build a bump at the upper and lowersubstrates of the LCD by exposure and development, so that the liquidcrystal molecules around the bump can produce a certain pre-inclinedangle and topple down toward the fixed direction. The second one is toform predetermined pattern of indium tin oxide (ITO) pixel electrodes atthe upper and lower substrates, which will generate an electric fieldwith a certain inclined angle to control the toppling direction of theliquid crystal molecules in the different regions. This is called aspatterned vertical alignment (PVA) technology. The third one is to formITO slits at the TFT side of the LCD substrate and full ITO at the otherside. And then add the polymerizable monomer into the liquid crystalmedium. First, make the liquid crystal molecules topple down by anelectric field, at the same time, irradiate the monomer with ultravioletlight to polymerize and form the polymer particles which can guide thetoppling direction of the liquid crystal molecules. The polymerparticles deposited on the surface of the substrate play the role of thealignment. This is called as polymer stabilized vertical alignment(PSVA).

The reaction rate of the polymerizable monomer, the size and thedistribution of the polymer, the surface uniformity of the substrate,and the strength of the alignment force have major impacts on theoptical properties of the panel and the stability of the production. Inaddition to the process conditions, these factors are mainly dependenton the molecular structure of the polymerizable monomer which directlydetermines the speed of the light reaction, the characteristics of thepolymer and the strength of the alignment force to the liquid crystal.Because the conventional liquid crystal medium comprises alkenylcompound, it is beneficial to obtain a low rotational viscosity toimprove the response of liquid crystal medium. The alkenyl compoundwithin the liquid crystal medium will affect the polymerization reactionof the polymerizable monomer easily and then the alignment of the liquidcrystal medium. Hence, in general, single polymerizable monomer is verydifficult to make the factors mentioned above in a favorable situation.The actual situation often attends to one thing and loses track ofanother, such as good uniformity of the polymer accompanied with lowalignment force, or strong alignment force accompanied with slowreaction rate and so on.

SUMMARY OF THE INVENTION

The technical issue to be solved by the present invention is to providea mixture for liquid crystal medium, wherein by using a polymerizablemonomer, the reaction rate of the polymerization reaction, theuniformity of the generated polymer and the strength of the alignmentforce can be balanced at the same time and reach a higher level.

The present invention further provides a liquid crystal displaycomprising the mixture for liquid crystal medium, wherein by using apolymerizable monomer, the reaction rate of the polymerization reactionof the monomer, the uniformity of the generated polymer and the strengthof the alignment force can be balanced at the same time and reach ahigher level, which improves the optical properties and overallperformance of the panel and the stable mass production.

In order to solve the technical issue, the embodiment according to thepresent invention provides a mixture for liquid crystal mediumcomprising: a liquid crystal material and a polymerizable monomer whichwill polymerize under UV irradiation, the liquid crystal materialcomprising an alkenyl compound which is stable to the polymerizationreaction during the polymerization of the polymerizable monomer, theweight percentage of the polymerizable monomer accounting for 0.1% to 1%of the total mixture for liquid crystal medium; the polymerizablemonomer defined by the following structural formula:

wherein, P represents a polymerizable group, which is selected from thegroup consisting of methacrylate group or acrylate group; m representsthe number of the polymerizable groups Ps connected to the same aromaticring, m represents 2 or 3; Y represents 1 or 2; R represents the alkylcontaining number of carbon atoms from 1 to 12; wherein the P ismethacrylate group when the Ps in formula I are different.

Wherein, the formula of the polymerizable monomer is as follows:

wherein, R represents the alkyl containing number of carbon atoms from 1to 12.

Wherein, any hydrogen on the aromatic ring in the structural formulas ofthe polymerizable monomer may be substituted by the group of —F, —Cl,—Br, methyl or —CN.

Wherein, the alkenyl compound is defined by the following structuralformulas:

wherein,

independently represents:

R1 represents the straight chain or branched chain alkenyl containingnumber of carbon atoms from 2 to 9;R2 represents the straight chain or branched chain alkyl containingnumber of carbon atoms from 1 to 12;X independently represents H

F

Cl

OCF₃ or CF₃;m represents from 1 to 4;n and k respectively represents from 0 to 3.

Correspondingly, another embodiment according to the present inventionfurther provides a liquid crystal display comprising: a upper substrateand a lower substrate which are parallel with each other, and a mixturefor liquid crystal medium provided between the upper substrate and thelower substrate, the mixture for liquid crystal medium comprising: aliquid crystal material and a polymerizable monomer which willpolymerize under UV irradiation, the liquid crystal material comprisingan alkenyl compound which is stable to the polymerization reactionduring the polymerization of the polymerizable monomer, the weightpercentage of the polymerizable monomer accounting for 0.1% to 1% of thetotal mixture for liquid crystal medium; the polymerizable monomerdefined by the following structural formula:

wherein, P represents a polymerizable group, which is selected from thegroup consisting of methacrylate group or acrylate group; m representsthe number of the polymerizable groups Ps connected to the same aromaticring, m represents 2 or 3; Y represents 1 or 2; R represents the alkylcontaining number of carbon atoms from 1 to 12; wherein the P ismethacrylate group when the Ps in formula I are different.

Wherein, the formula of the polymerizable monomer is as follows:

wherein, R represents the alkyl containing number of carbon atoms from 1to 12.

Wherein, any hydrogen on the aromatic ring in the structural formulas ofthe polymerizable monomer may be substituted by the group of —F, —Cl,—Br, methyl or —CN.

Wherein, the alkenyl compound is defined by the following structuralformulas:

wherein,

independently represents:

R1 represents the straight chain or branched chain alkenyl containingnumber of carbon atoms from 2 to 9;R2 represents the straight chain or branched chain alkyl containingnumber of carbon atoms from 1 to 12;X independently represents H, F, Cl, OCF₃ or CF₃;m represents from 1 to 4;n and k respectively represents from 0 to 3.

The embodiment according to the present invention has the beneficialeffects as follow:

the mixture for liquid crystal medium according to the presentinvention, by using a polymerizable monomer which will polymerize underUV irradiation and the appropriate content ratio, the polymer bump withsmall size and good uniformity can be obtained after the polymerization,which avoids the bad liquid crystal alignment and the light spotoccurred at the dark state of the liquid crystal panel, and thenincreases the response rapid of the liquid crystal panel to obtain highcontrast ratio. It improves the optical properties and overallperformance of the panel and the stable mass production when applied inthe liquid crystal display.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

In order to further illustrate technical means and effects thereofaccording to the present invention, the accompanying drawings and thefollowing detailed descriptions are the preferred embodiments of thepresent invention.

The present invention provides a mixture for liquid crystal medium usedfor liquid crystal display. The mixture for liquid crystal mediumcomprises: a liquid crystal material and a polymerizable monomer whichwill polymerize under UV irradiation. The weight percentage of thepolymerizable monomer accounts for 0.1% to 1% of the total mixture forliquid crystal medium.

Wherein, the weight percentage of the polymerizable monomer accounts for0.1% to 1% of the total mixture for liquid crystal medium, which iscomposed of a benzene ring. The benzene ring can be directly connectedwith polymerizable group. The polymerizable group is selected from thegroup consisting of methacrylate group or acrylate group. Thepolymerizable groups on the polymerizable monomer are all methacrylategroup when they are different.

In one embodiment, the polymerizable monomer is defined by the followingstructural formula:

wherein, P represents a polymerizable group, which is selected from thegroup consisting of methacrylate group or acrylate group; m representsthe number of the polymerizable groups Ps connected to the same aromaticring, m represents 2 or 3; Y represents 1 or 2; R represents the alkylcontaining number of carbon atoms from 1 to 12; wherein the P ismethacrylate group when the Ps in formula I are different.

Wherein, the formula of the polymerizable monomer is as follows:

wherein, R represents the alkyl containing number of carbon atoms from 1to 12.

Any hydrogen on the aromatic ring in the structural formulas of thepolymerizable monomer may be substituted by the group of —F, —Cl, —Br,methyl or —CN.

In one embodiment, the weight percentage of the polymerizable monomeraccounts for 0.3% of the total mixture for liquid crystal medium.

The alkenyl compound is defined by the following structural formulas:

wherein,

independently represents:

R1 represents the straight chain or branched chain alkenyl containingnumber of carbon atoms from 2 to 9;R2 represents the straight chain or branched chain alkyl containingnumber of carbon atoms from 1 to 12;X independently represents H

F

Cl

OCF₃ or CF₃;m represents from 1 to 4;n and k respectively represents from 0 to 3.

The preferred embodiment according to the present invention is describedas follows.

Embodiment 1

The mixture for liquid crystal medium is chosen from negative-typeliquid crystal material and two kinds of polymerizable monomers asfollows:

The structural formula of the liquid crystal material is

The structural formula of the polymerizable monomer, which is RM-A1, isas follows:

The content of RM-A1 accounts for 3000 ppm of the liquid crystal mediumlayer. In the mixture for liquid crystal medium, the polymer bump,formed after ultraviolet irradiation, has small and uniform size, andthe light spots won't occur at the dark state.

Embodiment 2

The mixture for liquid crystal medium is chosen from negative-typeliquid crystal material and a polymerizable monomer as follows:

The structural formula of the liquid crystal material is

The structural formula of the polymerizable monomer, which is RM-A2, isas follows:

The content of RM-A2 accounts for 3000 ppm of the liquid crystal mediumlayer. In the mixture for liquid crystal medium, the polymer bump,formed after ultraviolet irradiation, has small and uniform size, andthe light spots won't occur at the dark state.

Embodiment 3

The mixture for liquid crystal medium is chosen from negative-typeliquid crystal material and a polymerizable monomer as follows:

The structural formula of the liquid crystal material is

The structural formula of the polymerizable monomer, which is RM-A3, isas follows:

The content of RM-A3 accounts for 3000 ppm of the liquid crystal mediumlayer. In the mixture for liquid crystal medium, the polymer bump,formed after ultraviolet irradiation, has small and uniform size, andthe light spots won't occur at the dark state. In the other embodiment,the total content accounting for 1000 ppm, 8000 ppm and 10000 ppm of theliquid crystal medium layer also can be chosen.

In summary, the mixture for liquid crystal medium used for liquidcrystal display according to the present invention, by using apolymerizable monomer which will polymerize under UV irradiation, cancontrol the size and the uniformity of the polymer bump formed bypolymerization, which avoids the bad liquid crystal alignment and thelight spot occurred at the dark state of the liquid crystal panel, andthen obtains good optical performance of the liquid crystal panel, suchas high contrast ratio and high response speed.

The mixture for liquid crystal medium according to the present inventioncan be applied in display. The liquid crystal display according to thepresent invention uses the mixture for liquid crystal medium mentionedabove, which comprises a upper substrate and a lower substrate which areparallel with each other, and a mixture for liquid crystal mediumprovided between the upper substrate and the lower substrate. Themixture for liquid crystal medium is the mixture for liquid crystalmedium according to the present invention mentioned above and not berepeated here. By using the polymerizable monomer in the mixture forliquid crystal medium, the reaction rate of the polymerization reaction,the uniformity of the generated polymer and the strength of thealignment force can be balanced at the same time and reach a higherlevel. That is, while the reaction rate is quick, the uniformity of thegenerated polymer and the strength of the alignment force are also high,which improves the optical properties and overall performance of thepanel and the stable mass production.

It is to be understood that many other possible modifications andvariations can be made by those skilled in the art without departingfrom the spirit and scope of the invention as hereinafter claimed, andthose modifications and variations are considered encompassed in thescope of protection defined by the claims of the present invention.

1. A mixture for liquid crystal medium comprising: a liquid crystalmaterial and a polymerizable monomer which will polymerize under UVirradiation, the liquid crystal material comprising an alkenyl compoundwhich is stable to the polymerization reaction during the polymerizationof the polymerizable monomer, the weight percentage of the polymerizablemonomer accounting for 0.1% to 1% of the total mixture for liquidcrystal medium; the polymerizable monomer defined by the followingstructural formula:

wherein, P represents a polymerizable group, which is selected from thegroup consisting of methacrylate group or acrylate group; m representsthe number of the polymerizable groups Ps connected to the same aromaticring, m represents 2 or 3; Y represents 1 or 2; R represents the alkylcontaining number of carbon atoms from 1 to 12; wherein the Ps are notmethacrylate group simultaneously.
 2. The mixture for liquid crystalmedium as claimed in claim 1, characterized in that the formula of thepolymerizable monomer is as follows:

wherein, R represents the alkyl containing number of carbon atoms from 1to
 12. 3. The mixture for liquid crystal medium as claimed in claim 2,characterized in that any hydrogen on the aromatic ring in thestructural formula of the polymerizable monomer may be substituted bythe group of —F, —Cl, —Br, methyl or —CN.
 4. The mixture for liquidcrystal medium as claimed in claim 1, characterized in that the alkenylcompound is defined by the following structural formulas:

wherein,

independently represents:

R1 represents the straight chain or branched chain alkenyl containingnumber of carbon atoms from 2 to 9; R2 represents the straight chain orbranched chain alkyl containing number of carbon atoms from 1 to 12; Xindependently represents H

F

Cl

CF₃ or CF₃; m represents from 1 to 4; n and k respectively representsfrom 0 to
 3. 5. The mixture for liquid crystal medium as claimed inclaim 2, characterized in that the alkenyl compound is defined by thefollowing structural formulas:

wherein,

independently represents:

R1 represents the straight chain or branched chain alkenyl containingnumber of carbon atoms from 2 to 9; R2 represents the straight chain orbranched chain alkyl containing number of carbon atoms from 1 to 12; Xindependently represents H

F

Cl

OCF₃ or CF₃; m represents from 1 to 4; n and k respectively representsfrom 0 to
 3. 6. The mixture for liquid crystal medium as claimed inclaim 3, characterized in that the alkenyl compound is defined by thefollowing structural formulas:

wherein,

independently represents:

R1 represents the straight chain or branched chain alkenyl containingnumber of carbon atoms from 2 to 9; R2 represents the straight chain orbranched chain alkyl containing number of carbon atoms from 1 to 12; Xindependently represents H

F

Cl

OCF₃ or CF₃; m represents from 1 to 4; n and k respectively representsfrom 0 to
 3. 7. A liquid crystal display comprising: a upper substrateand a lower substrate which are parallel with each other, and a mixturefor liquid crystal medium provided between the upper substrate and thelower substrate, the mixture for liquid crystal medium comprising: aliquid crystal material and a polymerizable monomer which willpolymerize under UV irradiation, the weight percentage of thepolymerizable monomer accounting for 0.1% to 1% of the total mixture forliquid crystal medium; the liquid crystal material comprising an alkenylcompound which is stable to the polymerization reaction during thepolymerization of the polymerizable monomer, the polymerizable monomerdefined by the following structural formula:

wherein, P represents a polymerizable group, which is selected from thegroup consisting of methacrylate group or acrylate group; m representsthe number of the polymerizable groups Ps connected to the same aromaticring, m represents 2 or 3; Y represents 1 or 2; R represents the alkylcontaining number of carbon atoms from 1 to 12; wherein the Ps are notmethacrylate group simultaneously.
 8. The liquid crystal display asclaimed in claim 7, characterized in that the formula of thepolymerizable monomer is as follows:

wherein, R represents the alkyl containing number of carbon atoms from 1to
 12. 9. The liquid crystal display as claimed in claim 8,characterized in that any hydrogen on the aromatic ring in thestructural formulas of the polymerizable monomer may be substituted bythe group of —F, —Cl, —Br, methyl or —CN.
 10. The liquid crystal displayas claimed in claim 7, characterized in that the alkenyl compound isdefined by the following structural formulas:

wherein,

independently represents:

R1 represents the straight chain or branched chain alkenyl containingnumber of carbon atoms from 2 to 9; R2 represents the straight chain orbranched chain alkyl containing number of carbon atoms from 1 to 12; Xindependently represents H

F

Cl

OCF₃ or CF₃; m represents from 1 to 4; n and k respectively representsfrom 0 to
 3. 11. The liquid crystal display as claimed in claim 8,characterized in that the alkenyl compound is defined by the followingstructural formulas:

wherein,

independently represents:

R1 represents the straight chain or branched chain alkenyl containingnumber of carbon atoms from 2 to 9; R2 represents the straight chain orbranched chain alkyl containing number of carbon atoms from 1 to 12; Xindependently represents H

F

Cl

OCF₃ or CF₃; m represents from 1 to 4; n and k respectively representsfrom 0 to
 3. 12. The liquid crystal display as claimed in claim 9,characterized in that the alkenyl compound is defined by the followingstructural formulas:

wherein,

independently represents:

R1 represents the straight chain or branched chain alkenyl containingnumber of carbon atoms from 2 to 9; R2 represents the straight chain orbranched chain alkyl containing number of carbon atoms from 1 to 12; Xindependently represents H

F

Cl

OCF3 or CF3; m represents from 1 to 4; n and k respectively representsfrom 0 to 3.